There are several geophysical techniques which are specifically designed for use over water. All of these techniques require the use of a boat and an accurate method for determining position during data acquisition. Differential global position systems (GPS) are typically used for providing real time location data. Each of the commonly used techniques are summarized below:

ACOUSTIC SUB-BOTTOM PROFILING

Acoustic Sub-bottom Profiling is a geophysical technique that can be used to determine sub-bottom stratigraphy.  Sub-bottom profiling systems consist of an acoustic source, an array of hydrophones and a recording system.  The source emits acoustic energy into the water.  The energy is reflected off interfaces where the velocity of the energy changes.  The reflected energy is detected by the hydrophones and the data is stored by the recording system.

"CHIRP" SUB-BOTTOM PROFILER

CHIRP systems employ wideband frequency modulated (FM) “Chirp” technology.  The system transmits a linearly swept, wide band FM pulse into the water (commonly termed the “chirp” pulse).  When the acoustic pulse encounters material with different acoustic properties, a portion of the energy is reflected.  Reflections are received by the towfish and are processed to remove the FM carrier.  The measured reflections are displayed in real time as shades of gray on a computer monitor, and are stored on a hard drive for post processing.  This technique provides penetration that is comparable to low frequency narrow band systems with resolution comparable to high frequency narrow band systems.

BUBBLE PULSER

The bubble pulser is a compact, high efficiency seismic reflection profiling system. It is specifically designed to map thicknesses of sedimentary layers and the depth to bedrock in marine environments. Typically, the system is capable of penetrating 100 feet of material with a resolution of five feet. Use of the bubble pulser is limited to areas where the water depth is at least eight feet.

The system consists of a pulser with a resonant frequency of 300 Hz, a single channel seismic streamer and a graphic or digital recorder. The pulser and streamer are towed behind or next to a moving vessel. The pulser provides a seismic pulse approximately every second. The seismic pulses travel through the water and are reflected back to the surface from subsurface seismic interfaces. The reflected signal is detected by the seismic streamer. The seismic streamer signal is processed and recorded on a graphic or digital recorder. The amplitude of the reflected signal depends upon the velocity contrast between the various layers. The depths to the seismic interfaces can be computed from the travel times for the reflected waves in the velocity of the subsurface material is known or if the survey intersects an area of known geology.

The theory of operation of the kHz sub-bottom profiler and the bubble pulser are the same, and the amount of energy produced by the sources in each of the systems is approximately equal. The difference is that the kHz is tuned to a higher frequency than the bubble pulser. The increased frequency provides higher resolution of sub-bottom structures. However, the higher frequency also results in a decrease in penetration depth. The SBP is particularly useful for locating hard rock outcrops in areas of thinly bedded fine grained sediments. The SBP requires a minimum water depth of six feet and it can be used to water depths of hundreds of feet.

MARINE ELECTRICAL RESISTIVITY

A marine electrical resistivity survey is similar to a terrestrial survey except that a marine multi-electrode cable is placed on the lakebed.  The cable consists of twenty-five electrodes.  An Advanced Geosciences, Inc. control unit applies current and measures the potential from various pairs of electrodes to determine electrical resistivity as a function of depth along the electrode array.  The data are processed using a two-dimensional inversion program.  In the program, a non-linear least-squares optimization technique is used to automatically determine the best fit to the data.  This method is useful in determining the geologic conditions below the mudline.  For more information on this method, see our Electrical Resistivity page.

GROUND PENETRATING RADAR

Ground penetrating radar (GPR) uses FM-frequency radio energy to echo-locate subsurface features. Details of the technique are described in the attached sheet. The technique was originally developed to investigate subsurface features below ice sheets. The GPR method has been adapted for use over land or water. Over-water surveys are conducted by placing the radar antennae in rubber rafts. The rafts are towed behind or beside a moving vessel. Generally the GPR method is useful in fresh water at depths ranging from a few feet to twenty feet. Beyond twenty feet there is insufficient signal strength from most antennae to penetrate the sub-bottom material.

Side scan sonar is useful for mapping underwater topography and for identifying features on the surface of river and lake bottoms. The technique is capable of providing data to over one thousand feet on both sides of a moving vessel. A side scan sonar survey consists of towing a transmitter/receiver (towfish) from a moving vessel. The towfish transmits high intensity, high frequency bursts of acoustic energy into the water. The acoustic energy is transmitted in fan-shaped beams which are narrow in the horizontal plane and wide in the vertical plane. Objects or topographic features on the river bottom produce echoes which are received by the towfish. The signals are processed and printed on a graphic recorder or stored in a digital format. Generally, hard materials provide high amplitude echoes and soft, fine grained materials provide weak signals. Side scan sonar produces a visual representation of the surface of the lake or river bottom.